TWI831174B - Wafer cleaning apparatus and controlling method thereof - Google Patents

Abstract

The invention discloses a substrate cleaning device and a control method thereof. The substrate cleaning device includes: a vacuum chuck part for placing a wafer; an annular cover part facing the snap ring part of the wafer; and an expansion machine module to enable The annular cover is disposed in a moving manner, and applies pressure to the clamping ring portion toward the vacuum chuck portion to expand the distance between the die in the wafer; and the chuck module is disposed on the vacuum chuck portion to expand the wafer. The annular cover portion of the machine module that applies pressure is limited to the vacuum chuck portion.

Description

Substrate cleaning device and control method thereof

The present invention relates to a substrate cleaning device and a control method thereof. More specifically, it relates to a substrate cleaning device and a control method thereof that can improve substrate processing performance and reduce substrate processing time.

Generally speaking, in semiconductor processes, an etching process for etching a wafer, a separation process for cutting the wafer into a plurality of crystal grains, a cleaning process for cleaning the wafer, and the like are performed. The substrate processing device is used for the etching process or cleaning process of the wafer.

The substrate processing device is rotatably arranged and includes a rotary table on which the wafer is placed, a sealing ring annularly coupled to an edge area of the rotary table, and the like. While the turntable is rotating, the processing liquid is supplied to the wafer placed on the turntable.

However, when cleaning a wafer cut into a plurality of dies, it is difficult to remove foreign matter remaining in the gaps between the plurality of dies due to the existing substrate processing apparatus. In addition, in order to remove foreign matter from the gaps between the plurality of crystal grains, the cleaning time needs to be sufficiently extended, so the cleaning time may be increased.

Furthermore, the process of coupling the sealing ring to the upper part of the rotary table is cumbersome, and the coupling completion state of the sealing ring is not constant during coupling, so coupling errors (for example, misalignment, etc.) may occur. further If a coupling error occurs in the sealing ring, the structure around the turntable may be damaged as the processing fluid penetrates to the outside of the sealing ring.

Furthermore, a wafer fixing module is provided to prevent the position of the wafer from changing, and a sealing ring fixing module for fixing the sealing ring is provided. Therefore, the structure of the substrate processing apparatus becomes complicated, and the manufacturing cost may increase.

The prior art of the present invention is disclosed in Korean Patent Publication No. 10-2016-0122067 (published on October 21, 2016, invention title: wafer part processing device and sealing ring for wafer part processing device).

An object of the present invention is to provide a substrate processing apparatus and a control method thereof that can improve substrate processing performance and reduce substrate processing time.

The substrate cleaning device of the present invention includes: a vacuum chuck part for placing the wafer; an annular cover part facing the clasp part of the wafer; an expansion machine module arranged in a manner that the annular cover part can move, and The clamping ring portion applies pressure to the vacuum chuck portion side to expand the distance between the die in the wafer; and a chuck module is provided on the vacuum chuck portion to cover the annular cover portion that is pressed by the expansion machine module Limited to the vacuum chuck section.

The expander module includes: an expander moving part; an expander head set on the expander moving part; and a plurality of expander arms connected to the expander head to hold the annular cover to move the annular cover. And the plurality of expander arms exert pressure on the annular cover part, so that the chuck module restricts the annular cover part to the vacuum chuck part.

If the chuck module restricts the annular cover part to the vacuum chuck part, the expander arm releases the pressure on the annular cover part.

The expander head includes: an expander casing part, which is connected to the moving part of the expander; a plurality of expander slider parts, which are combined with the expander casing part in a radially movable manner, and are respectively connected to the expander arms. ; The expander rod part is arranged inside the expander casing part to move the plurality of expander slider parts; and the expander driving part is arranged in the expander casing part to move the expander rod part.

The expander casing part includes: a casing main part formed with a moving space for the expander rod to move; a first baffle part sealing one side of the casing main part; and a second baffle part sealing the casing A moving hole is formed on the other side of the main body for the dilator rod to be movably inserted.

The expander rod part includes: a moving disk part movably disposed in the moving space part of the expander casing part; a plunger part connected to the moving disk part by being inserted into the moving hole part of the expander casing part; and a pushing part connected to the plunger part and the expander slider part in such a manner that the expander slider part moves as the plunger part moves.

A conical portion is formed in the plunger portion, and the pushing portion can expand in the radial direction as the pushing portion is pressurized by the conical portion.

The expander driving part includes: a first supply port for supplying a driving medium to one side of the moving space part to move the moving disk part to the expander slider part side; and a second supply port for supplying a driving medium to the other side of the moving space part. The driving medium is supplied to the side to move the moving disk portion to the opposite side of the slider portion of the expander.

The expander arm includes: an arm member connected to the expander slider; and a hook portion disposed on the arm member to restrict the annular cover.

The hook part includes a hook main body part connected to the arm part so as to surround the outside of the annular cover part, and a hook pin part combined with the hook main body part so as to be inserted into the cover hole part of the annular cover part.

The chuck module includes: a chuck base, which is arranged on the vacuum chuck part; a chuck rotating part, which is connected to the chuck base to rotate the chuck base; and a plurality of chuck connecting rod parts, which are connected radially to the chuck base. connected, a plurality of chuck connecting rod parts move when the chuck base rotates; and a plurality of cover limiting parts respectively connected with the chuck connecting rod part to limit the annular cover part when the chuck connecting rod part moves In the vacuum chuck section.

The chuck base includes: a base main body formed in an annular shape concentric with the rotation axis of the vacuum chuck part; and a plurality of guide parts formed on the base main body for movably coupling the chuck connecting rod part ; And the base gear part is formed on the base body part and is connected to the chuck rotation part.

The guide part is formed to be inclined with respect to the radial direction of the base body part.

The chuck connecting rod part includes: a guide slider, which is movably arranged on the chuck base; a connecting rod component, which is connected to the guide slider and moves linearly along the radial direction of the chuck base when the guide slider moves; And a link gear portion is formed on the link member so as to engage with the cover restricting portion to move.

The chuck link portion further includes guide roller portions supporting both sides of the link member.

The cover restricting part includes: a cover restricting shaft part rotatably provided on the vacuum chuck part; a restricting gear part formed on the cover restricting shaft part to mesh with the connecting rod gear part; and a cover restricting lever connected to the cover restricting shaft part connected to pressurize and release the annular cover part; and a restricting roller part rotatably provided on the cover restricting rod to make rolling contact with the annular cover part.

The control method of the substrate cleaning device of the present invention includes the following steps: the expansion machine module restricts the annular cover part; the wafer is placed in the vacuum chuck part; the expansion machine module applies pressure to the annular cover part to expand the grains of the wafer spacing; the chuck module confines the annular cover to the vacuum chuck; and ultrasonic The cleaning module sprays cleaning fluid onto the wafer and applies ultrasonic waves to the cleaning fluid to cause the cleaning fluid to generate ultrasonic vibrations.

After the step of the chuck module restricting the annular cover part to the vacuum chuck part, it further includes a step of releasing the restriction of the annular cover part by the expander module and moving to the waiting position.

The step of restricting the annular cover of the expander module includes the following steps: the plurality of expander arms of the expander module move outward through the expander head; the hooks of the expander arms correspond to the annular cover; and as The plurality of expander arms move inward through the expander head, and the hook portion restricts the annular cover portion.

In the step of applying pressure to the annular cover portion of the expander module to expand the distance between the wafer grains, the expander arm portion of the expander module applies pressure to the retaining ring portion of the wafer to expand the distance between the wafer grains. .

In the step of the ultrasonic cleaning module spraying the cleaning liquid onto the wafer and applying ultrasonic waves to the cleaning liquid to cause the cleaning liquid to generate ultrasonic vibrations, the ultrasonic cleaning module applies ultrasonic waves to the cleaning liquid while being immersed in the cleaning liquid.

The ultrasonic cleaning module sprays the cleaning liquid onto the wafer and applies ultrasonic waves to the cleaning liquid to cause the cleaning liquid to generate ultrasonic vibrations. The steps include the following steps: the lifting arm rises through the lifting arm driving part; the swinging part causes the lifting arm to move toward the vacuum chuck. The upper side of the part rotates; the lifting arm driving part lowers the lifting arm part so that the cleaning head of the ultrasonic cleaning module is immersed in the cleaning fluid; and the cleaning fluid injection part sprays the cleaning fluid to the wafer, and the ultrasonic generation part generates the cleaning fluid Ultrasonic vibration.

When the lifting arm driving part lowers the lifting arm part so that the cleaning head of the ultrasonic cleaning module is immersed in the cleaning liquid, the internal pressure forming part can generate a pressure higher than atmospheric pressure inside the cleaning head.

In the step of the lifting arm driving part lowering the lifting arm part so that the cleaning head of the ultrasonic cleaning module is immersed in the cleaning liquid, the lower surface of the cleaning head may be configured such that the inflow side of the cleaning liquid is higher than the cleaning liquid. outflow side.

The cleaning head adjusts the height of one lower surface of the cleaning head according to the height change of the wafer.

In the step of lowering the lifting arm by the lifting arm driving unit so that the cleaning head of the ultrasonic cleaning module is immersed in the cleaning liquid, the lifting arm is lowered to maintain a predetermined distance between the cleaning head and the surface of the wafer. .

The injection nozzle of the cleaning liquid injection unit injects the cleaning liquid obliquely in the direction in which the cleaning liquid flows in the wafer.

The step of placing the wafer on the vacuum chuck section includes the following steps: the transfer unit receives the wafer from the transfer unit; the transfer unit moves to the upper side of the vacuum chuck section; and the transfer unit is lowered to place the wafer on the vacuum chuck. department.

The control method of the substrate cleaning device further includes the following steps: discharging the cleaning liquid after the cleaning time of the wafer is completed; and drying the wafer as the vacuum chuck part rotates.

The control method of the substrate cleaning device further includes the following steps: the expansion machine module moves to restrict the annular cover part; the chuck module releases the restriction on the annular cover part; the expander module moves to the waiting position; and discharges from the vacuum chuck part wafer.

According to the present invention, in the wafer, the cleaning process is performed with the distance between the crystal grains expanded. Therefore, foreign matter attached to the surface of the crystal grains and foreign matter located in the gaps between the plurality of crystal grains can be easily removed through the cleaning liquid. Therefore, the cleaning performance of the wafer can be significantly improved, and the defective rate of the wafer can be significantly reduced.

Furthermore, according to the present invention, as the chuck base rotates through the chuck rotating part, the annular cover part is restricted by the vacuum chuck part. Therefore, the wafer can be restricted in the vacuum chuck part by one chuck rotating part. Therefore, the structure of the substrate cleaning device can be simplified.

Furthermore, according to the present invention, the height adjustment part can adjust the installation height of the cover restriction part, so the height between the upper surface of the annular cover part and the upper surface of the vacuum chuck part can be adjusted. Therefore, by adjusting the tensile strength of the bonding sheet of the wafer, the spacing between the plurality of dies can be adjusted.

Furthermore, according to the present invention, the ultrasonic cleaning module sprays cleaning liquid onto the wafer, and applies ultrasonic waves to the cleaning liquid to cause the cleaning liquid to generate ultrasonic vibrations. Therefore, the wafer is cleaned through the chemical action of the cleaning liquid and physical cleaning is performed through the cavitation phenomenon of ultrasonic waves, so the cleaning efficiency of the wafer can be significantly improved.

10:wafer

11:Granules

12: Adhesive sheet

13: Snap ring part

100:Substrate cleaning device

101: Shell

102: Chamber Department

105: Cup-shaped housing

110:Drive Department

111:Rotation axis

113: Motor Department

120: Vacuum chuck department

122: Vacuum flow path section

124: Vacuum chamber

130: Ring cover

131: Cover main body

132:Restricted step part

133: Cover the pressurizing part

135: Cover hole part

140:Expander module

141: Expansion machine moving part

150: Expander head

151: Expansion machine casing department

152: Main part of casing

152a: Slider groove part

152b:Mobile Space Department

153: First baffle part

153a: First sealing component

153b:Lock ring part

154: Second baffle part

154a: Second sealing component

154b: Moving hole

155: Expander slider part

156: Expander rod

156a:Mobile disk

156b: Plunger part

156c:Push department

156d: Disc sealing parts

158: Expansion machine drive department

158a: First supply port

158b: Second supply port

160: Expander arm

161:Arm parts

163:Hook

164:Hook main body part

165:hook pin part

170:Chuck module

171:Chuck base

172:Base main body

173: Guidance Department

174: Base gear part

175:Chuck rotation part

180:Chuck connecting rod part

181: Guide slider

182: Connecting rod parts

183: Connecting rod gear part

184: Guide roller part

190: cover restriction part

191: Cover limit shaft part

192: Limiting gear part

193: Cover limit lever

194:Restriction roller part

210: Height adjustment module

211:Adjusting parts

213:Height adjustment part

220: Ultrasonic cleaning module

221:Lifting arm drive part

222:Lifting arm

223:Swing part

224: Ultrasonic cleaning department

225: Clean the head

225a: Combining bolt part

225b: Angle adjustment bolt part

226: Ultrasonic wave generation department

227: Voltage application part

228: Internal pressure forming part

229: Cleaning fluid injection part

229a: Cleaning fluid inflow part

229b:Injection nozzle

230: Cleaning fluid injection module

231:Swing arm drive part

232:Swing arm

233: Roundabout

234:Spraying Department

240:Ion generator

250:Transfer unit

251:Transfer Mobile Department

253:Transfer lift part

255:Transfer bearing part

G1, G2: interval

H1: height of inflow side

H2: Outflow side height

θ: angle

S11,S12,S13,S14,S15,S16,S17,S18,S19,S20,S21,S22,S23,S24,S25: Steps

FIG. 1 is a top view schematically showing a wafer processed in a substrate cleaning apparatus according to an embodiment of the present invention.

2 is a side view schematically showing a wafer processed in a substrate cleaning apparatus according to an embodiment of the present invention.

FIG. 3 is a side view schematically showing a substrate cleaning device according to an embodiment of the present invention.

4 is a schematic diagram illustrating that in the substrate cleaning device according to an embodiment of the present invention, as the expander module descends and applies pressure to the annular cover part and the retaining ring part of the wafer, the distance between the plurality of die expands. Side view of the state.

5 is a perspective view schematically illustrating a state in which the expansion machine module holds and moves the annular cover in the substrate cleaning device according to one embodiment of the present invention.

6 is a side view schematically showing the expansion machine module, annular cover part and vacuum chuck part in the substrate cleaning device according to one embodiment of the present invention.

7 is a cross-sectional view schematically showing a state in which the chuck module restricts the annular cover in the substrate cleaning device according to one embodiment of the present invention.

FIG. 8 is a perspective view schematically showing an expansion machine module in a substrate cleaning device according to an embodiment of the present invention.

9 is a cross-sectional view schematically showing the expansion head of the expansion machine module in the substrate cleaning device according to an embodiment of the present invention.

10 is a cross-sectional view schematically illustrating a state in which the expander slider unit moves to the inside of the expander head in the expander module of the substrate cleaning device according to one embodiment of the present invention.

FIG. 11 is a top view schematically showing a chuck module in a substrate cleaning device according to an embodiment of the present invention.

12 is a top view schematically showing a state in which the chuck link portion is driven as the chuck base of the chuck module rotates in the substrate cleaning device according to one embodiment of the present invention.

13 is a perspective view schematically showing a state in which the cover restricting portion of the chuck module is driven to restrict the annular cover portion in the substrate cleaning device according to an embodiment of the present invention.

14 is a plan view schematically showing a state in which the ultrasonic cleaning module and the cleaning liquid injection module are arranged outside the vacuum chuck part in the substrate cleaning device according to one embodiment of the present invention.

FIG. 15 is a top view schematically showing an ultrasonic cleaning module in a substrate cleaning device according to an embodiment of the present invention.

FIG. 16 is a side view schematically showing an ultrasonic cleaning module in a substrate cleaning device according to an embodiment of the present invention.

17 is a side view schematically showing a state in which the cleaning head of the ultrasonic cleaning module is arranged obliquely on the wafer in the substrate cleaning device according to an embodiment of the present invention.

18 is a cross-sectional view schematically showing the coupling bolt portion and the angle adjustment bolt portion of the cleaning head in the substrate cleaning device according to an embodiment of the present invention.

19 is a cross-sectional view schematically showing a state in which an angle adjustment bolt portion is provided in the substrate cleaning device according to one embodiment of the present invention.

20 is a side view schematically showing the ion generator and transfer unit of the substrate cleaning device according to one embodiment of the present invention.

FIG. 21 is a flowchart illustrating a control method of a substrate cleaning device according to an embodiment of the present invention.

Hereinafter, embodiments of the substrate cleaning device and its control method of the present invention will be described with reference to the accompanying drawings. In the process of explaining the substrate cleaning device and its control method, the thickness of the lines or the size of the structural elements shown in the drawings may be enlarged for clarity and convenience of explanation. In addition, the terms used below are defined taking into consideration the functions in the present invention, and may differ depending on the intention or practice of the user or application person. Therefore, such terms should be defined in the context of this disclosure.

FIG. 1 is a top view schematically showing a wafer processed in a substrate cleaning apparatus according to an embodiment of the present invention. FIG. 2 is a side view schematically showing a wafer processed in a substrate cleaning apparatus according to an embodiment of the present invention. FIG. 3 is a side view schematically showing a substrate cleaning device according to an embodiment of the present invention. FIG. 4 schematically shows that in the substrate cleaning device according to an embodiment of the present invention, as the expander module descends and applies pressure to the annular cover part and the retaining ring part of the wafer, the distance between the plurality of die expands. Side view of the state.

Referring to FIGS. 1 to 4 , a substrate cleaning device 100 according to an embodiment of the present invention includes a vacuum chuck part 120 , an annular cover part 130 , an expander module 140 and a chuck module 170 .

The substrate cleaning device 100 cleans the wafer 10 . As the wafer 10 etched in the etching process is cut into a matrix shape in the separation process, a plurality of crystal grains 11 are formed. In the cleaning process, as the cleaning liquid is sprayed onto the wafer 10 , foreign matter adhering to the plurality of die 11 is removed. Various types of liquids such as deionized water (DI-water) can be used as cleaning fluids.

The wafer 10 includes: a plurality of die 11 arranged in a matrix; an adhesive sheet 12 for the plurality of die 11 to attach; and a snap ring portion 13 connected to the periphery of the adhesive sheet 12 to tightly support the adhesive sheet 12 . The adhesive sheet 12 is made of a material that can stretch in the horizontal direction. As the adhesive sheet 12 is tightened by the snap ring portion 13, the plurality of die 11 are fixed in position, and the die 11 of the thin plate maintains a flat state.

A chamber 102 is formed inside the housing 101 , and a cup-shaped housing 105 is provided in the chamber 102 . The vacuum chuck portion 120 is arranged inside the cup-shaped housing 105 that contains cleaning fluid. The cup-shaped housing 105 is provided to surround the outside of the vacuum chuck portion 120 . The cleaning liquid sprayed onto the cup-shaped housing 105 (see FIG. 14 ) can be prevented from being discharged or splashed to the outside through the cup-shaped housing 105 .

The vacuum chuck portion 120 is rotatably provided on the driving portion 110 . The vacuum chuck part 120 may have a disk shape as a whole.

The driving part 110 includes a rotating shaft 111 connected to the rotation center of the vacuum chuck part 120 and a motor part 113 provided on the rotating shaft 111. The motor part 113 includes a stator (not shown) disposed inside a casing (not shown); and a rotor (not shown) disposed inside the stator and surrounding the rotation shaft 111 . In addition, the driving part 110 may adopt a belt driving method in which the rotating shaft 111 is rotated through a transmission belt or a chain driving method in which the rotating shaft 111 is rotated through a transmission chain. As long as the vacuum chuck part 120 can be rotated, the driving part 110 may be used. Adopt various forms of driving methods.

The rotating shaft 111 is formed with a vacuum flow path portion 122 that creates a vacuum in the vacuum chuck portion 120 . The vacuum flow path portion 122 is formed along the longitudinal direction of the rotation shaft 111 . A vacuum chamber 124 is formed in the vacuum chuck part 120 and is connected to the vacuum flow path part 122 . A plurality of vacuum holes (not shown) are formed in the vacuum chuck part 120 to apply vacuum pressure to the wafer 10 , and the vacuum chuck part 120 can be formed in various forms.

The wafer 10 is placed in the vacuum chuck unit 120 . The wafer 10 cut into a plurality of die 11 is placed in the vacuum chuck unit 120 . When the wafer 10 is cut into die 11 , foreign matter may remain in the gap between the surface of the die 11 and the die 11 .

The annular cover portion 130 is opposite to the retaining ring portion 13 of the wafer 10 . The annular cover part 130 includes: a cover main body part 131 formed to surround the periphery of the vacuum chuck part 120; a restriction step part 132 formed to protrude inward from the lower side of the cover main body part 131; and a cover pressure part 133 formed from the lower side of the cover main body part 131. The upper side of the cover body part 131 extends inward and applies pressure to the retaining ring part 13 of the wafer 10 (see FIG. 7 ). The thickness of the cover pressing portion 133 may gradually become thinner toward the end. The cover pressure portion 133 can seal the upper side of the snap ring portion 13 , thereby preventing the cleaning liquid from penetrating into components outside the snap ring portion 13 .

The expander module 140 is disposed in such a manner that the annular cover part 130 can move, and applies pressure on the snap ring part 13 toward the vacuum chuck part 120 to expand the gap G1 between the die 11 in the wafer 10 .

The chuck module 170 is provided in the vacuum chuck part 120 to fix the snap ring part 13 of the wafer 10 in the vacuum chuck part 120 . The chuck module 170 fixes the snap ring portion 13 to the surrounding portion of the vacuum chuck portion 120 by pressing the snap ring portion 13 downward. Therefore, when the vacuum chuck part 120 rotates, the chuck module 170 presses the annular cover part 130 and the retaining ring part 13 to prevent the position of the wafer 10 from changing and maintain the wafer 10 in a flat state. In the following, this chuck module 170 will be described in detail.

5 is a perspective view schematically illustrating a state in which the expansion machine module holds the annular cover and moves it in the substrate cleaning device according to one embodiment of the present invention. A side view of the expander module, the annular cover part and the vacuum chuck part in the substrate cleaning device. Figure 7 is a schematic view of the chuck module restricting the annular cover part in the substrate cleaning device according to one embodiment of the present invention. Figure 8 is a schematic cross-sectional view of the expansion machine module in the substrate cleaning device according to one embodiment of the present invention. Figure 9 is a schematic view of the expansion machine module in the substrate cleaning device according to one embodiment of the present invention. 10 is a cross-sectional view schematically illustrating a state in which the expander slider moves toward the inside of the expander head in the expander module of the substrate cleaning device according to one embodiment of the present invention.

Referring to FIGS. 5 to 10 , the expander module 140 includes a expander moving part 141 , a expander head 150 and a plurality of expander arm parts 160 .

The expansion machine moving part 141 is provided on the upper side of the vacuum chuck part 120 so as to be movable up and down. The expander moving part 141 may adopt various forms, such as a robot arm form and a ball screw form provided so as to be able to move up and down. The dilator head 150 is disposed movably through the dilator moving part 141 . The plurality of expander arms 160 are connected to the expander head 150 to hold the annular cover 130 to move it and apply pressure to the annular cover 130 so that the chuck module 170 restricts the annular cover 130 to a vacuum. Chuck part 120. A plurality of dilator arms 160 are arranged radially on the dilator head 150 . Four or more expander arms 160 may be provided around the expander head 150 .

In a state where the plurality of expander arms 160 exert pressure on the annular cover 130 , the chuck module 170 restricts the annular cover 130 to the vacuum chuck 120 . Therefore, the clamping ring 13 of the wafer 10 passes through the annular cover. The portion 130 moves downward. In this case, as the annular cover 130 descends, the adhesive sheet 12 of the wafer 10 is pulled in the radial direction, and the adhesive sheet 12 is stretched in the radial direction. As the adhesive sheet 12 is stretched in the radial direction, multiple wafers 10 are pulled in the radial direction. The gap G1 between the particles 11 will expand (refer to Fig. 4). If the cleaning liquid is sprayed onto the plurality of crystal grains 11 in a state where the distance G2 between the plurality of crystal grains 11 is enlarged, the foreign matter attached to the surface of the crystal grains 11 and the foreign matters located on the plurality of crystal grains 11 can be easily removed through the cleaning liquid. Foreign matter in the gap between. Therefore, it can To significantly improve the foreign matter cleaning performance in the wafer 10 . Moreover, as the cleaning performance of the wafer 10 is significantly improved, the defective rate of the wafer 10 can be significantly reduced.

Furthermore, when the chuck module 170 restricts the annular cover 130 to the vacuum chuck 120 , the expander arm 160 releases the pressure on the annular cover 130 . Furthermore, the expander moving part 141 moves the expander head part 150 and the expander arm part 160 to the upper side of the vacuum chuck part 120. Therefore, it is possible to prevent the ultrasonic cleaning module 220 from colliding with the expander module 140 or being disturbed when moving toward the upper side of the wafer 10 .

The dilator head 150 includes a dilator sleeve part 151 , a plurality of dilator slider parts 155 , a dilator rod part 156 and a dilator driving part 158 .

The expander sleeve part 151 is connected to the expander moving part 141 . The expander sleeve part 151 may be cylindrical as a whole. A plurality of dilator slider parts 155 are radially movably coupled to the dilator sleeve part 151 and are respectively connected to the dilator arm part 160 . In this case, a slider groove portion 152a is formed radially around the dilator sleeve portion 151 so that the dilator slider portion 155 is movably coupled. The dilator rod portion 156 is disposed inside the dilator sleeve portion 151 to move the plurality of dilator slider portions 155 . The dilator rod part 156 is disposed inside the dilator sleeve part 151 in a vertically movable manner. The expander driving part 158 is disposed on the expander sleeve part 151 to move the expander rod part 156 .

When the expander driving part 158 is driven, the expander slider part 155 moves in the radial direction in the expander sleeve part 151 as the expander rod part 156 moves. As the dilator slider portion 155 moves toward the outside of the dilator sleeve portion 151 , the dilator arm portion 160 moves outward and releases the restriction on the annular cover portion 130 , and as the dilator slider portion 155 moves toward the expander cannula. The inward movement of the portion 151 causes the expander arm portion 160 to move inward and restrict the annular cover portion 130 .

The expander sleeve part 151 includes a sleeve main body part 152, a first baffle part 153 and a second baffle part 154.

The sleeve main body 152 is formed with a moving space 152b for the dilator rod 156 to move. The movement space part 152b may have a cylindrical shape. The first baffle portion 153 is provided to close one side of the sleeve main body portion 152 . The first baffle portion 153 is detachably provided on the upper side of the casing main body portion 152 . A first sealing member 153a is provided around the first baffle portion 153 . A lock ring portion 153b is provided on one side of the first baffle portion 153 to prevent the first baffle portion 153 from being separated from the casing main body portion 152 . After the expander rod part 156 is inserted into the movement space part 152b, the first baffle part 153 closes one side of the cannula main body part 152. The second baffle part 154 closes the other side of the sleeve main part 152 and forms a moving hole part 154b for the dilator rod part 156 to be movably inserted. A second sealing member 154a is provided around the moving hole 154b to seal the gap with the dilator rod 156. The dilator rod 156 is provided movably in the up-and-down direction.

The dilator rod part 156 includes a moving plate part 156a, a plunger part 156b, and a pushing part 156c.

The moving plate part 156a is movably provided in the moving space part 152b. A disk sealing member 156d is provided around the moving disk part 156a to seal the gap between the inner surface of the dilator sleeve part 151 and the outer surface of the moving disk part 156a. The moving disk part 156a has a disk shape. The plunger part 156b is connected to the moving plate part 156a so that it may be inserted into the moving hole part 154b. Combined with the center part of the plunger part 156b. The pushing part 156c is connected to the plunger part 156b and the dilator slider part 155, so as to move the dilator slider part 155 as the plunger part 156b moves. As the pushing part 156c descends to apply pressure to the expander slide part 155, the expander slide part 155 moves outward, and as the pushing part 156c rises to release the pressure on the expander slide part 155, The expander slider part 155 moves inward.

A conical portion (not shown) is formed on the plunger portion 156b, and as the pushing portion 156c is pressed by the conical portion, the pushing portion 156c will expand in the radial direction. Then, as the conical portion releases the pressure on the pushing portion 156c, the pushing portion 156c contracts in the radial direction through the restoring force. The pushing part 156c may be through a spring (not shown) The connecting structure may be formed of a stretchable material so that a plurality of push pieces (not shown) can expand and contract.

The expander drive unit 158 includes a first supply port 158a that supplies a drive medium to one side of the movement space portion 152b so that the moving plate portion 156a moves toward the expander slider portion 155; and a second supply port 158b that moves toward the expander slider portion 155. The driving medium is supplied to the other side of the space part 152b so that the moving plate part 156a moves to the side opposite to the expander slider part 155. The first supply port 158a is connected to the first supply line, and the second supply port 158b is connected to the second supply line. If the first supply port 158a supplies the driving medium to one side of the movement space part 152b, the second supply port 158b discharges the driving medium to the other side of the movement space part 152b. If the drive medium is supplied to one side, the first supply port 158a discharges the drive medium to one side of the movement space portion 152b. Therefore, as the driving medium is supplied to the first supply port 158a or the second supply port 158b, the moving disk portion 156a can move to one side or the other side of the moving space portion 152b, and therefore, the expander arm portion 160 can move in the cannula. The body portion 152 moves radially.

The expander arm 160 includes an arm member 161 connected to the expander slider 155 and a hook 163 disposed on the arm member 161 to restrict the annular cover 130 . The arm member 161 is arranged in the radial direction of the casing main body 152 . The hook 163 is arranged at the end of the arm member 161 . When the dilator slider part 155 moves inward of the cannula main body part 152, the hook part 163 restricts the annular cover part 130.

」形態，以與環形蓋部130的外側邊角部接觸。鉤銷部165以向鉤主體部164的內側突出的方式形成。隨著臂部件161透過 擴張機滑塊部155而向內側移動，鉤銷部165插入環形蓋部130的蓋孔部135，因此，當擴張機模組140移動時，能夠防止環形蓋部130從擴張機模組140脫離。 The hook part 163 includes: a hook main part 164 connected to the arm member 161 to surround the outside of the annular cover part 130; and a hook pin part 165 combined with the hook main part 164 to be inserted into the cover hole part 135 of the annular cover part 130 . The hook body portion 164 can be generally in the shape of "

" form, so as to contact the outer corner portion of the annular cover portion 130. The hook pin portion 165 is formed to protrude inward of the hook main body portion 164 . As the arm member 161 moves inward through the expander slider part 155 , the hook pin part 165 is inserted into the cover hole part 135 of the annular cover part 130 . Therefore, when the expander module 140 moves, the annular cover part 130 can be prevented from being removed from the cover hole 135 . The expander module 140 is detached.

FIG. 11 is a schematic top view of the chuck module in the substrate cleaning device according to one embodiment of the present invention. FIG. 12 is a schematic view of the chuck module in the substrate cleaning device according to one embodiment of the present invention. A top view of the state in which the chuck base rotates and the chuck link portion is driven. Figure 13 is a schematic diagram showing that in the substrate cleaning device according to one embodiment of the present invention, the cover restricting portion of the chuck module restricts the annular cover portion. A perspective view of the driven state.

Referring to FIGS. 11 to 13 , the chuck module 170 includes a chuck base 171 , a chuck rotating part 175 , a plurality of chuck link parts 180 and a plurality of cover restricting parts 190 .

The chuck base 171 is provided in the vacuum chuck part 120 . The chuck rotating part 175 is connected to the chuck base 171 to rotate the chuck base 171 . The plurality of chuck link portions 180 are radially connected to the chuck base 171 and move when the chuck base 171 rotates. The plurality of cover restricting parts 190 are respectively connected to the chuck link part 180 to fix the annular cover part 130 to the vacuum chuck part 120 when the chuck link part 180 moves.

As the chuck rotating part 175 is driven, the base gear part 174 rotates. As the base main body part 172 rotates together with the base gear part 174 , the chuck link part 180 moves in the radial direction of the base main body part 172 . In this case, when the base body portion 172 of the chuck base 171 rotates, the plurality of chuck link portions 180 will rotate simultaneously. As the chuck link portions 180 move, the annular cover portion 130 is fixed to the vacuum chuck. Department 120. Therefore, one chuck base 171 and one chuck rotating part 175 can be used to simultaneously fix the wafer 10 and the annular cover part 130 to the vacuum chuck part 120. Therefore, the structure of the substrate cleaning device 100 can be further simplified.

The chuck base 171 includes a base body part 172, a plurality of guide parts 173, and a base gear part 174.

The base body portion 172 has an annular shape so as to be concentric with the rotation axis 111 of the vacuum chuck portion 120 . The base body part 172 is arranged inside the vacuum chuck part 120 . A plurality of guide portions 173 are formed on the base body portion 172 so that the chuck link portion 180 can be movably coupled. The number of the guide portions 173 is the same as the number of the chuck link portions 180 , and they are formed at equal intervals along the circumferential direction of the base body portion 172 . The base gear portion 174 is formed on the base body portion 172 and is connected to the chuck rotation portion 175 . The base gear portion 174 is arranged in an arc shape on the inner peripheral surface of the base body portion 172 . As the chuck rotating part 175 is driven, the base gear part 174 rotates. As the base main body part 172 rotates together with the base gear part 174 , the chuck link part 180 moves in the radial direction of the base main body part 172 .

The guide portion 173 is formed to be inclined relative to the radial direction of the base body portion 172 . The guide part 173 may be a guide hole part. The guide portion 173 may be a guide groove or a guide protrusion. Since the guide portion 173 is formed obliquely with respect to the radial direction of the base body 172 , as the base body 172 rotates at a certain angle, the chuck link portion 180 linearly moves in the radial direction of the base body 172 .

The chuck link portion 180 includes a guide slider 181 , a link member 182 , and a link gear portion 183 .

The guide slider 181 is movably coupled to the guide portion 173 . The link member 182 is connected to the guide slider 181 , and when the guide slider 181 moves, it linearly moves along the radial direction of the base body 172 . The link gear portion 183 is formed on the link member 182 so as to engage with the cover restricting portion 190 and move. The link member 182 has a straight rod shape. The link gear portion 183 is formed in the form of a parallel rack in the longitudinal direction of the link member 182 .

The chuck link portion 180 further includes guide roller portions 184 that support both sides of the link member 182 . When the base body 172 rotates, the guide roller portion 184 prevents the chuck link portion 180 from moving towards the base body 172 . 172 degrees of rotation in the circumferential direction. Therefore, when the base body portion 172 rotates and the guide slider 181 moves along the guide roller portion 184, the link member 182 does not rotate but moves linearly.

The cover restricting part 190 includes: a cover restricting shaft part 191 rotatably provided on the vacuum chuck part 120; a restricting gear part 192 formed on the cover restricting shaft part 191 to mesh with the link gear part 183; and a cover restricting lever. 193 is connected to the cover limiting shaft portion 191 to pressurize and depressurize the annular cover portion 130; and the limiting roller portion 194 is rotatably provided on the cover limiting rod 193 to be in rolling contact with the annular cover portion 130.

As the link member 182 moves linearly, the link gear portion 183 meshes with the restriction gear portion 192 and is driven. As the restriction gear portion 192 rotates, the cover restriction shaft portion 191 and the cover restriction lever 193 rotate, and the restriction roller portion 194 moves in rolling contact with the restriction step portion 132 of the annular cover portion 130 . Therefore, the restriction roller portion 194 is in rolling contact with the restriction step portion 132 of the annular cover portion 130 , thereby preventing the generation of foreign matter due to wear or scratches of the restriction step portion 132 of the annular cover portion 130 . Therefore, the defective rate of the wafer 10 can be reduced by suppressing foreign matter from flowing into the wafer 10 located inside the annular cover 130 .

The substrate cleaning device 100 further includes a height adjustment module 210 provided on the vacuum chuck part 120 to adjust the height of the cover restriction part 190 . The height adjustment module 210 adjusts the height of the cover restriction portion 190 before starting the cleaning process.

When the installation height of the cover restricting part 190 is adjusted by the height adjustment part 213, the height between the upper surface of the annular cover part 130 and the upper surface of the vacuum chuck part 120 is adjusted. As the installation height of the cover restricting portion 190 is adjusted, the height of the restricting roller portion 194 of the cover restricting portion 190 is adjusted. In this case, if the annular cover portion 130 is restricted by the cover restriction portion 190 while the snap ring portion 13 is pressed, the stretching degree of the adhesive sheet 12 of the wafer 10 is adjusted according to the restriction height of the snap ring portion 13 . For example, the lower the installation height of the cover restricting portion 190 is, the greater the degree of stretching of the adhesive sheet 12 is. The higher the installation height of the cover restricting portion 190 is, the greater the degree of stretching of the adhesive sheet 12 is. 12 has a smaller degree of stretch. As the stretching degree of the adhesive sheet 12 is adjusted, the spacing between the plurality of crystal grains 11 can be adjusted.

The height adjustment module 210 includes: an adjustment part 211 provided with a cover restriction part 190 that is movably coupled to the surrounding part of the vacuum chuck part 120; and a height adjustment part 213 connected with the adjustment part 211 to adjust the adjustment part 211 set height. The adjustment member 211 may have a block shape arranged around the vacuum chuck part 120 so as to be movable up and down. The height adjustment part 213 may adopt various forms such as a cylinder or a ball screw for adjusting the height of the adjustment member 211.

The height adjustment module 210 can adjust the height of the cover restriction part 190 so that the height difference between the upper surface of the vacuum chuck part 120 and the upper surface of the snap ring part 13 is generally in the range of 5 mm to 15 mm. The installation height of the cover restricting portion 190 can be appropriately adjusted taking into account the size of the wafer 10 , the cleaning speed of the wafer 10 , and the like.

14 is a top view schematically illustrating a state in which the ultrasonic cleaning module and the cleaning liquid injection module are arranged outside the vacuum chuck part in the substrate cleaning device according to an embodiment of the present invention. A top view of the ultrasonic cleaning module in the substrate cleaning device according to one embodiment of the present invention. Figure 16 is a schematic side view of the ultrasonic cleaning module in the substrate cleaning device according to one embodiment of the present invention. Figure 17 is a schematic view of the ultrasonic cleaning module in the substrate cleaning device according to one embodiment of the present invention. In the substrate cleaning device according to one embodiment of the invention, the cleaning head of the ultrasonic cleaning module is tilted and arranged on the wafer. Figure 18 is a schematic view of the cleaning head in the substrate cleaning device according to one embodiment of the invention. 19 is a cross-sectional view schematically illustrating the state in which the angle adjustment bolt part is provided in the substrate cleaning device according to one embodiment of the present invention.

Referring to FIGS. 14 to 19 , the substrate cleaning device 100 further includes an ultrasonic cleaning module 220 that sprays cleaning liquid onto the wafer 10 and applies ultrasonic waves to the cleaning liquid to cause the cleaning liquid to generate ultrasonic vibrations. move. In this case, the wafer 10 is cleaned through the chemical action of the cleaning liquid and physically cleaned through the cavitation phenomenon of ultrasonic waves. Therefore, the cleaning efficiency of the wafer 10 can be significantly improved.

The ultrasonic cleaning module 220 applies ultrasonic waves to the cleaning liquid while being soaked in the cleaning liquid. Therefore, voiding can be effectively generated on the underside of the ultrasonic cleaning module 220 .

The ultrasonic cleaning module 220 includes a lifting arm driving part 221, a lifting arm part 222, a swing part 223 and an ultrasonic cleaning part 224. A motor, a cylinder or a ball screw may be provided as the lifting arm driving part 221. The lifting arm portion 222 is connected to the lifting arm driving portion 221 so as to be raised and lowered through the lifting arm driving portion 221 . The swing part 223 is connected to the lifting arm part 222 to rotate the lifting arm part 222. The ultrasonic cleaning part 224 is connected to the lifting arm part 222, sprays cleaning liquid to the wafer 10, and applies ultrasonic waves to the cleaning liquid. While the wafer 10 is placed in the vacuum chuck unit 120 , the swing unit 223 is disposed outside the vacuum chuck unit 120 . After the wafer 10 is placed in the vacuum chuck unit 120 , the swing unit 223 moves toward the edge of the vacuum chuck unit 120 . Move upward.

The ultrasonic cleaning part 224 includes a cleaning head 225, an ultrasonic wave generating part 226, a voltage applying part 227, an internal pressure forming part 228, and a cleaning liquid injection part 229. The ultrasonic cleaning unit 224 is arranged outside the cup-shaped housing 105 .

The cleaning head 225 is connected to the lifting arm 222 . The ultrasonic wave generating part 226 is arranged inside the cleaning head 225 to apply ultrasonic waves to the cleaning liquid. The voltage applying part 227 is arranged inside the cleaning head 225 to apply voltage to the ultrasonic wave generating part 226 . The voltage applying part 227 is connected to an electric wire (not shown). The internal pressure forming part 228 is provided in the cleaning head 225 to create a pressure higher than atmospheric pressure inside the cleaning head 225 . The cleaning liquid ejection part 229 is formed in the cleaning head 225 to inject cleaning liquid to the wafer 10 . When the voltage applying part 227 applies a voltage to the ultrasonic wave generating part 226, ultrasonic waves are generated in the ultrasonic wave generating part 226 and the cleaning liquid vibrates ultrasonic waves. In this case, the internal pressure forming part 228 creates a pressure higher than the atmospheric pressure inside the cleaning head 225 , thereby preventing the cleaning liquid from flowing into the inside of the cleaning head 225 . because This can prevent the voltage applying part 227 and the ultrasonic wave generating part 226 from causing leakage or damage due to the cleaning liquid.

The cleaning liquid ejection part 229 includes a cleaning liquid inflow part 229a for inflowing the cleaning liquid, and a plurality of ejection nozzles 229b for injecting the cleaning liquid discharged from the cleaning liquid inflow part 229a onto the wafer 10 . Regarding the plurality of spray nozzles 229b, one or more rows may be formed on the lower side of the cleaning head 225. The injection nozzles 229 b are arranged along the radial direction of the wafer 10 . The plurality of spray nozzles 229b spray the cleaning liquid onto the wafer 10, so the wafer 10 can be cleaned by the spray pressure of the cleaning liquid. Furthermore, the plurality of spray nozzles 229 b are arranged along the radial direction of the wafer 10 . Therefore, when the wafer 10 is rotated through the vacuum chuck part 120 , the cleaning liquid can be sprayed onto the wafer 10 while the position of the cleaning head 225 is fixed. .

The plurality of spray nozzles 229b are tilted at a certain angle in the direction in which the cleaning liquid flows in the wafer 10 to spray the cleaning liquid (see FIG. 17 ). For example, when the wafer 10 rotates in the clockwise direction, the plurality of injection nozzles 229 b inject the cleaning liquid obliquely in the clockwise direction with the cleaning head 225 as a reference. Furthermore, when the wafer 10 rotates in the counterclockwise direction, the plurality of injection nozzles 229 b inject the cleaning liquid obliquely in the counterclockwise direction with the cleaning head 225 as a reference. Since the cleaning liquid is guided to flow out smoothly from the lower side of the cleaning head 225, stagnation of the cleaning liquid can be prevented and fluidity of the cleaning liquid can be ensured.

The lower surface portion of the cleaning head 225 is formed such that the inflow side of the cleaning liquid is higher than the outflow side of the cleaning liquid (inflow side height H1 > outflow side height H2 ). Therefore, it is possible to prevent the cleaning liquid from colliding with the inflow side corners of the cleaning head 225 and becoming stagnant. Furthermore, after the cleaning liquid flows smoothly toward the lower surface portion of the cleaning head 225 , it can flow out of the lower surface portion of the cleaning head 225 more quickly.

The cleaning head 225 further includes: a plurality of coupling bolt parts 225a, which are screw-connected to the cleaning head 225 and the lifting arm part 222; and an angle adjustment bolt part 225b, which is screw-connected to the cleaning head 225 and the lifting arm part 222 to adjust cleaning. The angle θ of the head 225 (refer to FIG. 17 ) (refer to FIGS. 18 and 19 ). knot A plurality of coupling bolt portions 225a and angle adjustment bolt portions 225b are provided on both sides of the cleaning head 225 in the width direction. As the angle adjustment bolt part 225b protrudes and is coupled to the cleaning head 225, the cleaning head 225 and one side of the lifting arm part 222 can be slightly separated, so that the coupling bolt part 225a is coupled to the cleaning head 225 and the lifting arm part 222. Therefore, as the cleaning head 225 is coupled to the lifting arm 222 in a slightly inclined state, the installation angle of the cleaning head 225 can be adjusted. The installation angle of the cleaning head 225 can be appropriately designed by considering conditions such as the rotation speed of the wafer 10 , the size of the wafer 10 , the distance between the cleaning heads 225 , and the viscosity of the cleaning liquid.

The substrate cleaning apparatus 100 further includes a cleaning liquid injection module 230 for injecting cleaning liquid onto the wafer 10 . The cleaning liquid injection module 230 can spray a cleaning liquid containing deionized water (DIW) and nitrogen to the wafer 10 .

The cleaning liquid injection module 230 includes a swing arm driving part 231 , a swing arm part 232 , a swing part 233 and a spray part 234 .

A motor, a cylinder, or a ball screw are provided as the swing arm driving part 231 . The swing arm portion 232 is connected to the swing arm driving portion 231 so as to be raised and lowered through the swing arm driving portion 231 . The swing portion 233 is connected to the swing arm portion 232 to rotate the swing arm portion 232 . The spray part 234 is connected to the rotating arm part 232 and is used to spray the cleaning liquid onto the wafer 10 .

The spray portion 234 may include a spray nozzle. A spray nozzle sprays the cleaning liquid onto the wafer 10 . Therefore, when the wafer 10 rotates through the vacuum chuck part 120 , the spray part 234 repeatedly rotates within a certain angle range and sprays the cleaning liquid onto the wafer 10 .

The ultrasonic cleaning module 220 and the cleaning liquid injection module 230 can be selectively used according to the processing process of the wafer 10 .

20 is a side view schematically showing the ion generator and transfer unit of the substrate cleaning device according to one embodiment of the present invention.

Referring to FIG. 20 , an ion generator 240 is provided inside the housing 101 . The ion generator 240 is disposed above the chamber unit 102 and is used to remove static electricity generated during processing steps and non-processing steps of the wafer 10 . The ion generator 240 prevents static electricity from being generated inside the wafer 10 and the chamber part, and therefore can prevent foreign matter from adhering to the wafer 10 again due to static electricity.

If air is supplied as the supply gas to the ion generator 240 and deionized water is supplied as the cleaning liquid, the cations and anions ionized by the ion generator 240 can be sprayed on the upper part of the wafer together with the cleaning liquid.

Before spraying deionized water containing cations and anions onto the upper part of the wafer 10 , the electrostatic potential of the wafer 10 was measured to be approximately 3.6 KV. In contrast, after spraying deionized water containing cations and anions to the upper part of the wafer 10, the measured electrostatic potential was approximately -0.10 KV to -0.17 KV. For such a negative voltage, the static electricity of the wafer 10 can be controlled to an ideal value close to “0” by increasing the amount of (+) ions generated by the ion generator 240 .

A transfer unit 250 is provided in the chamber part 102 to receive the wafer 10 from a transfer unit (not shown). The transfer unit 250 includes a transfer moving part 251 movably provided on the bottom surface of the chamber part 102; a transfer lifting part 253 provided on the transfer moving part 251; and a transfer carrying part 255 provided on the transfer lifting part 253. When the wafer 10 transferred from the transfer unit is placed on the transfer carrying part 255 , the transfer lifting part 253 moves to both sides of the vacuum chuck part 120 through the transfer transfer part. When the transfer lift unit 253 lowers the transfer carrier unit 255 , the wafer 10 is placed on the upper side of the vacuum chuck unit 120 . After the wafer 10 is placed in the vacuum chuck part 120 , the transfer unit 250 returns to the original position so that the wafer 10 can be received from the transfer unit.

The control method of the substrate cleaning device according to an embodiment of the present invention as described above is explained.

FIG. 21 is a flowchart illustrating a control method of a substrate cleaning device according to an embodiment of the present invention.

Referring to FIG. 21 , the expansion machine module 140 restricts the annular cover 130 (step S11 ). In this case, as the plurality of expander arms 160 of the expander module 140 move outward through the expander head 150, the hook portions 163 of the expander arms 160 correspond to the annular cover portion 130, and as the plurality of expander arms 160 move outward through the expander head 150, The dilator arm 160 moves inward through the dilator head 150 , and the hook 163 restricts the annular cover 130 .

The transfer unit 250 places the wafer 10 on the vacuum chuck part 120 (step S12). In this case, the transfer unit 250 receives the wafer 10 from the transfer unit. As the transfer unit 250 moves to both sides of the vacuum chuck unit 120 , the transfer carrier unit 255 moves to the upper side of the vacuum chuck unit 120 . , the transfer carrying part 255 of the transfer unit 250 descends to place the wafer 10 on the vacuum chuck part 120 . If the wafer 10 is placed in the vacuum chuck part 120 , the transfer unit 250 returns to the original position so that a new wafer 10 can be received.

The expander module 140 descends and applies pressure to the annular cover 130 (step S13 ), so as to expand the distance between the die 11 of the wafer 10 . In this case, the expander module 140 holds the annular cover 130 and moves it toward the upper side of the wafer 10 . As the expander module 140 descends, the expander arm 160 of the expander module 140 moves against the annular cover 130 . 130 applies pressure to the lower side. When the annular cover portion 130 applies downward pressure to the snap ring portion 13 and moves downward, the adhesive sheet 12 of the wafer 10 is pulled in the radial direction, and the adhesive sheet 12 is stretched in the radial direction. As the bonding sheet 12 is stretched in the radial direction, the intervals between the plurality of crystal grains 11 will expand.

If the expander module 140 fully pressurizes the annular cover part 130, the chuck module 170 restricts the annular cover part 130 to the vacuum chuck part 120 (step S14). That is, if the chuck rotating part 175 of the chuck module 170 is driven by engaging with the base gear part 174, the chuck link part 180 moves outward as the chuck base 171 rotates a certain angle. As the link gear portion 183 of the chuck link portion 180 is driven by meshing with the restriction gear portion 192 of the cover restriction portion 190 , the cover restriction lever 193 and the restriction roller portion 194 rotate and restrict the restriction step portion 132 of the annular cover portion 130 . As the cover restricting portion 190 restricts the annular cover portion 130 , the retaining ring portion 13 of the wafer 10 remains in a lowered state, so that the distance between the die 11 in the wafer 10 is maintained in a state of widening.

If the cover restricting part 190 completely restricts the annular cover part 130, the expansion machine module 140 releases the restriction on the annular cover part 130 and moves to the waiting position (step S15). In this case, the expander module 140 is sufficiently separated from the vacuum chuck part 120 to prevent the ultrasonic cleaning module 220 from colliding or contacting when the ultrasonic cleaning module 220 moves to the upper side of the vacuum chuck part 120 .

The ultrasonic cleaning module 220 sprays the cleaning liquid onto the wafer 10 and generates ultrasonic vibration in the cleaning liquid (step S16). In this case, the ultrasonic cleaning module 220 applies ultrasonic waves to the cleaning liquid while being soaked in the cleaning liquid. That is to say, the lifting arm part 222 rises through the lifting arm driving part 221, the swing part 223 rotates the lifting arm part 222 to the upper side of the vacuum chuck part 120, and the lifting arm driving part 221 lowers the lifting arm part 222 to perform ultrasonic cleaning. The cleaning head 225 of the module 220 is immersed in the cleaning liquid, the cleaning liquid spraying part 229 sprays the cleaning liquid toward the wafer 10 , and the ultrasonic wave generating part 226 causes the cleaning liquid to generate ultrasonic vibration.

In this case, the distance between the plurality of crystal grains 11 is maintained in an enlarged state. Therefore, foreign matter between the crystal grains 11 can be removed more quickly and easily. Moreover, the wafer 10 can be cleaned more quickly and cleanly through the spray pressure of the cleaning fluid and the ultrasonic vibration of the cleaning fluid.

It is determined whether the cleaning time of the wafer 10 has ended (step S17). In this case, the cleaning time of the wafer 10 can be set in advance through the control unit (not shown).

If the cleaning time of the wafer 10 ends, the cleaning liquid will be discharged from the cup-shaped housing 105 (step S18). The cleaning fluid discharged from the cup-shaped housing 105 is again recovered into a cleaning fluid recovery tank (not shown).

Then, the ultrasonic cleaning module 220 moves to the outside of the vacuum chuck part 120 (step S19). In this case, the lifting arm driving part raises the lifting arm part 222 , and as the swing part 223 rotates the lifting arm part 222 , the ultrasonic cleaning part 224 moves to the outside of the vacuum chuck part 120 .

It is determined whether the discharge of the cleaning liquid is completed (step S20). In this case, the cleaning liquid discharge time is preset in the control unit. Furthermore, whether the cleaning fluid is completely discharged from the cup-shaped housing 105 can be detected through a discharge detection sensor (not shown).

As the vacuum chuck unit 120 rotates, the wafer 10 is dried (step S21). In this case, the cleaning liquid is not supplied to the cup housing 105 . As the vacuum chuck part 120 rotates, the cleaning liquid remaining in the wafer 10 is removed from the wafer 10 by centrifugal force. In this case, when the die 11 of the wafer 10 is enlarged, the wafer 10 can be rotated through the vacuum chuck part 120 , so the cleaning liquid remaining between the die 11 can be removed more quickly. In addition, as air or gas is sprayed onto the wafer 10 , drying of the wafer 10 can be accelerated.

The expansion machine module 140 moves to restrict the annular cover 130 (step S22). In this case, the expander module 140 is lowered toward the vacuum chuck part 120 side, and the hook part 163 of the expander arm part 160 faces the annular cover part 130. When the dilator head 150 moves the dilator arm 160 inward, the hook main body 164 is in close contact with the annular cover 130 , and the hook pin 165 of the hook 163 is inserted into the cover hole 135 of the annular cover 130 . The annular cover 130 is restrained.

The chuck module 170 releases the restriction on the annular cover 130 (step S23). In this case, when the chuck rotating part 175 rotates the chuck base 171 by a certain angle, the chuck link part 180 moves toward the center part of the chuck base 171 . As the link gear portion 183 is driven by meshing with the restriction gear portion 192 , the cover restriction lever 193 and the restriction roller portion 194 are separated from the restriction step portion 132 of the annular cover portion 130 . Even when the restriction on the annular cover 130 is released, the expander module 140 maintains a state of applying pressure to the annular cover 130 .

The expansion machine module 140 moves to the waiting position (step S24). In this case, as the expander moving part 141 rises, the expander head part 150 and the expander arm part 160 rise. If the expander arm is 160 When the annular cover portion 130 is raised while being restricted, the retaining ring portion 13 of the wafer 10 rises, and the adhesive sheet 12 of the wafer 10 shrinks back to its original state. Therefore, the distance between the crystal grains 11 of the wafer 10 returns to its original state.

The wafer 10 is discharged from the vacuum chuck unit 120 (step S25). In this case, the transfer moving part 251 of the transfer unit 250 moves to both sides of the vacuum chuck part 120, and the transfer lifting part 253 descends. As the transfer carrying part 255 rotates, the wafer 10 is carried on the transfer carrying part 255 . When the transfer unit 251 is transferred to the discharge position of the wafer 10 , the transfer unit receives the wafer 10 and discharges the wafer 10 to the outside of the chamber unit 102 . The transfer unit transfers the wafer 10 to a wafer storage unit or a subsequent process.

Although the present invention has been described with reference to the embodiments shown in the drawings, these are only illustrative examples, and those with ordinary skill in the relevant technical fields will understand that the present invention can be implemented with various modifications and other equivalent embodiments.

Therefore, the true scope of protection of the present invention is defined by the scope of the patent application.

100:Substrate cleaning device

110:Drive Department

111:Rotation axis

113: Motor Department

120: Vacuum chuck department

122: Vacuum flow path section

124: Vacuum chamber

130: Ring cover

140:Expander module module

150: Expander head

160: Expander arm

170:Chuck module module

180:Chuck connecting rod part

190: cover restriction part

210: Height adjustment module module

Claims (20)

A substrate cleaning device includes: a vacuum chuck part for placing a wafer; an annular cover part opposite a snap ring part of the wafer; and an expansion machine module to enable the annular cover part to is arranged in a moving manner, and applies pressure to the clasp part to the side of the vacuum chuck part, so as to expand the distance between the die in the wafer; and a chuck module is arranged on the vacuum chuck part to The annular cover portion exerted pressure by the expander module is restricted to the vacuum chuck portion; when the chuck module restricts the annular cover portion to the vacuum chuck portion, the expander module releases the annular cover portion. Apply pressure to the lid. The substrate cleaning device of claim 1, wherein the expander module includes: an expander moving part; an expander head disposed on the expander moving part; and a plurality of expander arm parts, and the expander arm part The expander head is connected to hold the annular cover to move the annular cover, and the plurality of expander arms exert pressure on the annular cover so that the chuck module restricts the annular cover to The vacuum chuck section. The substrate cleaning device of claim 2, wherein if the chuck module restricts the annular cover part to the vacuum chuck part, the expander arm releases the pressure on the annular cover part. The substrate cleaning device according to claim 2, wherein the expander head includes: an expander sleeve portion connected to the expander moving portion; a plurality of expander slider portions capable of radial movement Combined with the expander sleeve part and connected to the expander arm part respectively; an expander rod part arranged inside the expander sleeve part to move the plurality of expander slider parts; and an expander rod part is arranged inside the expander sleeve part to move the plurality of expander slider parts; The expander drive unit is disposed on the expander sleeve portion to move the expander rod portion. The substrate cleaning device according to claim 4, wherein the expander casing part includes: a casing main body part forming a moving space part for the expander rod part to move; a first baffle part sealing the One side of the casing main body part; and a second baffle part, sealing the other side of the casing main body part, and forming a moving hole part for the dilator rod part to be movably inserted. The substrate cleaning device according to claim 4, wherein the expander rod part includes: a moving plate part movably disposed in a moving space part of the expander sleeve part; and a plunger part to Connected to the moving plate part by inserting a moving hole part of the expander sleeve part; and A pushing part is connected with the plunger part and the expander slider part in a manner that the dilator slider part moves as the plunger part moves. The substrate cleaning device of claim 4, wherein the expander arm includes: an arm component connected to the expander slider; and a hook portion disposed on the arm in a manner to restrict the annular cover. part. The substrate cleaning device as claimed in claim 1, wherein the chuck module includes: a chuck base provided on the vacuum chuck part; and a chuck rotating part connected to the chuck base so that the chuck The disc base rotates; a plurality of chuck connecting rod portions are respectively connected radially with the chuck base, and the plurality of chuck connecting rod portions move when the chuck base rotates; and a plurality of cover limiting portions are respectively connected with the chuck base. The chuck link portion is connected to constrain the annular cover portion to the vacuum chuck portion when the chuck link portion moves. The substrate cleaning device according to claim 8, wherein the chuck base includes: a base main body formed in an annular shape concentric with the rotation axis of the vacuum chuck; and a plurality of guide portions formed on the vacuum chuck. a base body part for the chuck connecting rod part to be movably combined; and a base gear part formed on the base body part and connected with the chuck rotating part. The substrate cleaning device according to claim 9, wherein the guide portion is formed to be inclined relative to a radial direction of the base body portion. A method for controlling a substrate cleaning device, including the following steps: an expansion machine module restricts an annular cover; a wafer is placed in a vacuum chuck; the expansion machine module applies pressure to the annular cover to expand the spacing of the wafer's die; a chuck module restricts the annular cover part to the vacuum chuck part; and an ultrasonic cleaning module sprays cleaning liquid to the wafer, and applies ultrasonic waves to the cleaning liquid to clean The liquid generates ultrasonic vibration; when the chuck module restricts the annular cover part to the vacuum chuck part, the expander module releases the pressure on the annular cover part. The control method of the substrate cleaning device according to claim 11, wherein after the chuck module restricts the annular cover part to the vacuum chuck part, it further includes the expansion machine module releasing the annular cover limit and move to a waiting position. The control method of the substrate cleaning device according to claim 11, wherein the step of restricting the annular cover by the expansion machine module includes the following steps: a plurality of expansion machine arms of the expansion machine module pass through an expansion machine head Move outward; a hook portion of the expander arm corresponds to the annular cover portion; and As the dilator arms move inward through the dilator head, the hook restricts the annular cover. The control method of a substrate cleaning device as claimed in claim 11, wherein in the step of the ultrasonic cleaning module spraying cleaning liquid onto the wafer and applying ultrasonic waves to the cleaning liquid to cause the cleaning liquid to generate ultrasonic vibrations, the ultrasonic cleaning module The module applies ultrasonic waves to the cleaning fluid while being immersed in the cleaning fluid. The control method of a substrate cleaning device as claimed in claim 14, wherein the ultrasonic cleaning module sprays cleaning fluid onto the wafer and applies ultrasonic waves to the cleaning fluid to cause the cleaning fluid to generate ultrasonic vibrations, including the following steps: one lifting and lowering The arm portion rises through the lifting arm driving portion; a swing portion causes the lifting arm portion to rotate toward the upper side of the vacuum chuck portion; the lifting arm driving portion lowers the lifting arm portion to move a cleaning head of the ultrasonic cleaning module The wafer is immersed in the cleaning liquid; and a cleaning liquid spraying part sprays the cleaning liquid onto the wafer, and an ultrasonic wave generating part causes the cleaning liquid to generate ultrasonic vibration. The control method of the substrate cleaning device according to claim 15, wherein in the step of the lifting arm driving part lowering the lifting arm part so that the cleaning head of the ultrasonic cleaning module is immersed in the cleaning liquid, An internal pressure forming part forms a pressure higher than atmospheric pressure inside the cleaning head, or the lower surface part of the cleaning head is configured such that the inflow side of the cleaning liquid is higher than the outflow side of the cleaning liquid. The control method of the substrate cleaning device according to claim 15, wherein, In the step of the lifting arm driving part lowering the lifting arm part so that the cleaning head of the ultrasonic cleaning module is immersed in the cleaning liquid, so as to maintain a predetermined distance between the cleaning head and the surface of the wafer. method to lower the lifting arm. The control method of a substrate cleaning device as claimed in claim 11, wherein the step of placing the wafer in the vacuum chuck part includes the following steps: a transfer unit receives the wafer from a transfer unit; the transfer unit transfers the wafer to the vacuum chuck. The upper side of the vacuum chuck part moves; and the transfer unit is lowered so that the wafer is placed on the vacuum chuck part. The control method of a substrate cleaning device as claimed in claim 18, further comprising the following steps: discharging the cleaning liquid after the cleaning time of the wafer is over; and drying the wafer as the vacuum chuck part rotates. The control method of the substrate cleaning device according to claim 18, further comprising the following steps: the expansion machine module moves to restrict the annular cover; the chuck module releases the restriction of the annular cover; the expansion machine The module moves to a waiting position; and the wafer is ejected from the vacuum chuck part.

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